Method of making compressible elastomeric spring

ABSTRACT

A method of making a compressible elastomeric spring including at least one compressible elastomeric pad enclosed by a pair of metal plates includes the steps of forming plates with a center aperture and a plurality of prongs positioned about a peripheral edge thereof, forming each end of the pad with an axial projection and abutting groove, aligning the plurality of prongs with each respective projection and respective groove and applying axial force to one end of the spring to frictionally interlock the plurality of prongs with such projection and groove. The method also provides for making a multi-tiered stack of pads separated by plates in the above described manner and pre-shortening the spring prior to installation into the conventional yoke. The above described method additionally improves axial straightness and lateral stability of the multi-tiered spring assembly.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is related to and claims priority from ProvisionalPatent Application Ser. No. 60/926,987 filed on May 1, 2007. Thisapplication is a divisional of a prior non provisional application Ser.No. 12/150,929, filed May 1, 2008. This application is further closelyrelated to co-pending U.S. Ser. No. 12/150,809 entitled “CompressibleElastomeric Spring”, to co-pending U.S. Ser. No. 12/150,926 entitled“Plate for A Compressible Elastomeric Spring” now issued as U.S. Pat.No. 7,857,273 on Dec. 28, 2010, to co-pending U.S. Ser. No. 12/150,928entitled “Elastomeric Pad For A Compressible Elastomeric Spring”, toco-pending U.S. Ser. No. 12/150,925 entitled “Method Of MakingElastomeric Pad For A Compressible Elastomeric Spring” now issued asU.S. Pat. No. 7,981,348 on Jun. 26, 2011, to co-pending U.S. Ser. No.12/150,777 entitled “Combination Yoke and Elastomeric Draft Gear” nowissued as U.S. Pat. No. 8,136,683 on Mar. 20, 2012, to co-pending U.S.Ser. No. 12/150,808 entitled “Combination Yoke and Elastomeric DraftGear Having A Friction Mechanism” now issued as U.S. Pat. No. 8,096,431on Jan. 17, 2012, and to co-pending U.S. Ser. No. 12/150,927 entitled“Elastomeric Draft Gear Having A Housing” now issued as U.S. Pat. No.8,096,432 on Jan. 17, 2012, filed concurrently herewith. Theseapplications are being assigned to the assignee of the present inventionand the disclosures of these co-pending applications are herebyincorporated by reference thereto.

FIELD OF THE INVENTION

The present invention relates, in general, to compressible elastomericsprings capable of absorbing energy and, more particularly, thisinvention relates to a method for making elastomeric compressiblespring.

BACKGROUND OF THE INVENTION

Compressible elastomeric springs, including a multi-tiered stack ofelastomeric pads separated by plates, have been extensively employed forabsorbing energy and have gained wide acceptance for absorbing andcushioning buff and draft dynamic impact forces encountered duringmake-up and operation of a railway vehicle. U.S. Pat. No. 4,198,037 toAnderson and U.S. Pat. No. 5,351,844 to Carlstedt disclose related priorart methods of making compressible elastomeric springs.

Carlstedt is particularly concerned with a method of improvingcenter-grip metal plate and its mechanical interlocking to anelastomeric pad in order to improve lateral stability of thecompressible elastomeric spring.

However, further improvements are required in the method of mechanicallyinterlocking the plate to the elastomeric pad during a cold formingprocess and improving axial straightness and lateral stability of thecompressible elastomeric spring, particularly enabling the spring toabsorb and cushion higher levels of buff and draft dynamic impact force.

SUMMARY OF THE INVENTION

In accordance with one aspect, the present invention provides a methodof making a compressible elastomeric spring. The method includes thestep of providing at least one compressible elastomeric pad defining acentral axis and having a pair of axial ends. Each of the pair of axialends has each of a substantially flat surface disposed normal to thecentral axis and a central raised projection formed thereon. Next,providing a pair of plate like members. Each of the pair of plate likemembers has at least one substantially flat surface, one of an apertureand a cavity provided in at least one substantially flat surface thereofand a predetermined plurality of prongs positioned about a peripheraledge of such one of the aperture and cavity and extending at apredetermined angle relative to at least one substantially flat surfaceof each plate like member. Then, positioning such at least one padbetween the pair of plate like members. Axially aligning thepredetermined plurality of the prongs of each plate like member with arespective central projection. Finally, forming the compressibleelastomeric spring.

In accordance with another aspect, the present invention provides amethod of making a multi-tiered compression spring assembly including apredetermined plurality of axially disposed compressible elastomericpads, a first end plate on one end of the assembly, a second end plateon an opposed end of the assembly and a separator plate between eachpair of adjacent compressible elastomeric pads. The method includes thestep of forming each plate with an axial aperture. Next, forming apredetermined plurality of prongs about a peripheral edge of the axialaperture. Then, extending the predetermined plurality of prongs at apredetermined angle relative to a surface of the plates which is injuxtaposition to one of the predetermined plurality of compressibleelastomeric pads. Positioning the plates and the predetermined pluralityof compressible elastomeric pads to form the multi-tiered compressionspring assembly. Next, applying a predetermined axial force to themulti-tiered compression spring assembly. Then, piercing, with thepredetermined plurality of prongs and the applied force, an axial end ofa respectively juxtaposed compressible elastomeric pad. Penetrating,with the predetermined plurality of prongs and the applied force, apredetermined distance into such respectively juxtaposed compressibleelastomeric pad. Next, mechanically interlocking, by way of the prongpenetration, the predetermined plurality of compressible elastomericpads with the plates. Finally, removing the axial force from themulti-tiered compression spring assembly.

In accordance with a further aspect, the present invention discloses amethod of providing at least one of axial straightness and lateralstability in a multi-tiered compression spring assembly duringrepetitive cushioning of axial dynamic impact loads in excess of 7,500pounds per square inch (PSI) and in absence of a center rod orperipheral guidance. The spring assembly includes a predeterminedplurality of axially disposed compressible elastomeric pads formed froma preselected copolyester polymer having a modified molecular structureand having a predetermined shape factor and a separator plate betweeneach pair of adjacent compressible elastomeric pads. The method includesthe step of forming each axial end of each of the predeterminedplurality of pads with an axial projection. Next, forming each axial endwith a groove in abutting relationship with a peripheral side surface ofthe axial projection. Then, forming each separator plate with an axialaperture and with a predetermined plurality of prongs positioned about aperipheral edge of the axial aperture and extending at a predeterminedangle relative to a surface of each separator plate which is injuxtaposition to one of the compressible elastomeric pads. Next,positioning the separator plates and the predetermined plurality ofcompressible elastomeric pads to form the multi-tiered compressionspring assembly. Then, aligning the predetermined plurality of prongswith each of a respective axial projection and groove. Applying apredetermined axial force to one end of the multi-tiered compressionspring assembly. Next, piercing, with the predetermined plurality ofprongs and the applied force, each of an exterior surface of the axialprojection and a surface of the groove of a respectively juxtaposedcompressible elastomeric pad. Then, penetrating, with the predeterminedplurality of prongs and the applied force, a predetermined distance intothe respectively juxtaposed compressible elastomeric pad. Mechanicallyinterlocking, by way of the prong penetration, the predeterminedplurality of compressible elastomeric pads with the plates. Finally,removing the axial force from the multi-tiered compression springassembly.

OBJECTS OF THE INVENTION

It is, therefore, one of the primary objects of the present invention toprovide a method of making a compressible elastomeric spring includingan elastomeric pad positioned between a pair of plates.

Another object of the present invention is to provide a method of makinga compressible elastomeric spring stack of elastomeric pads separated byplates that improves mechanical interlocking of the metal plates to thecompressible elastomeric pad.

Yet another object of the present invention is to provide a method ofmaking a compressible elastomeric spring stack of elastomeric padsseparated by plates that improves axial straightness of the stack duringuse.

A further object of the present invention is to provide a method ofmaking a compressible elastomeric spring stack of elastomeric padsseparated by plates that improves lateral stability of the stack duringuse.

Yet a further object of the present invention is to provide a method ofmaking a compressible elastomeric spring stack of elastomeric padsseparated by plates that does not require use of center rod or axialguiding during use.

An additional object of the present invention is to provide a method ofmaking a compressible elastomeric spring stack of elastomeric padsseparated by plates that enables the spring to absorb and cushion higherdynamic impact forces during make-up and operation of a railway vehicle.

Another object of the present invention is to provide a method ofpre-shortening a compressible elastomeric spring stack of elastomericpads separated by plates prior to installation of the spring into aconventional yoke of a railway vehicle.

In addition to the several objects and advantages of the presentinvention which have been described with some degree of specificityabove, various other objects and advantages of the invention will becomemore readily apparent to those persons who are skilled in the relevantart, particularly, when such description is taken in conjunction withthe attached drawing Figures and with the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an isometric view of a compressible elastomeric spring of thepresent invention, particularly illustrating the method ofpre-shortening the spring prior to its installation into a yoke of therailway vehicle;

FIG. 2 is an isometric view of a compressible elastomeric spring of FIG.1, particularly illustrating the spring installed into the yoke in apre-shortened condition;

FIG. 3 is an isometric cross-sectional view of a compressibleelastomeric spring constructed in accordance with one embodiment of theinvention;

FIG. 4 is a cross-sectional elevation view of a compressible elastomericspring constructed in accordance with another embodiment of theinvention; and

FIG. 5 is an isometric view of a draft gear assembly employingcompressible elastomeric spring.

BRIEF DESCRIPTION OF THE VARIOUS EMBODIMENTS OF THE INVENTION

Prior to proceeding to the more detailed description of the presentinvention, it should be noted that, for the sake of clarity andunderstanding, identical components which have identical functions havebeen identified with identical reference numerals throughout the severalviews illustrated in the drawing figures.

It is to be understood that the definition of a railway vehicle appliesbut is not limited to passenger railcar, freight railcar, locomotive andthe like railway vehicles.

The present invention provides several methods of making a compressibleelastomeric spring. The various structures of the related springsproduced by the methods of the present invention are disclosed in theco-pending U.S. Ser. No. 12/150,809 entitled “Compressible ElastomericSpring”. Furthermore, the general methods of forming compressibleelastomeric spring are disclosed in U.S. Pat. Nos. 4,198,037 and5,351,844, whose teachings are incorporated into this document byreference thereto.

In accordance with one embodiment of the present invention, the methodincludes the step of providing at least one compressible elastomericpad, generally designated as 110, defining a central axis and having apair of axial ends. Each of the pair of axial ends has each of asubstantially flat surface disposed normal to the central axis and acentral raised projection formed thereon. The structure of suchcompressible elastomeric pad 110 is best disclosed in the co-pendingU.S. Ser. No. 12/150,928 entitled “Elastomeric Pad For A CompressibleElastomeric Spring”. Then, the method includes the step of providing apair of members to cage or enclose the compressible elastomeric pad 110therebetween. Preferably, each of the pair of members is a plate likemember, generally designated as 150, having at least one substantiallyflat surface, an aperture 180 provided in at least one substantiallyflat surface thereof and a predetermined plurality of prongs 170positioned about a peripheral edge 182 of the aperture 180 and extendingat a predetermined angle relative to at least one substantially flatsurface of each plate like member 150. Such plate like member 150 isbest shown and described in the co-pending U.S. Ser. No. 12/150,926entitled “Plate For A Compressible Elastomeric Spring”.

Next, the compressible elastomeric pad 110 is positioned between thepair of plate like members 150 followed by alignment of thepredetermined plurality of the prongs 170 of each plate like member 150with a respective central projection 130 of the compressible elastomericpad 110. After the compressible elastomeric pad 110 and the plate likemembers 150 are axially aligned, the compressible elastomeric spring 100can be formed.

To form the compressible elastomeric spring 100 of the presentinvention, a predetermined force is applied axially to an exposedsurface of one of the pair of plate like members 150. When the axialforce is applied, each of the predetermined plurality of prongs 170pierces an exterior surface of the central projection 130 and penetratesa predetermined distance at least into the central projection 130providing for frictional engagement between the prongs 170 and thecentral projection 130 and establishing a mechanical interlock betweenthe compressible elastomeric pad 110 and the abutting plate like member150. The applied axial force is removed when such interlock is achieved.

It has been found that to achieve the above described mechanicalinterlock, the compressible elastomeric pad 110 must be precompressedagain, to a height which is generally identical to the solid height ofsuch compressible elastomeric pad 110. It has been also found that theaxial force required to precompress the compressible elastomeric pad 110and achieve the mechanical interlock with abutting plate like members150 is between about 700,000 pounds and about 800,000 pounds.Advantageously, during the forming process, the applied axial force andthe construction of the prongs 170 enables each central projection 130to axially extend into the aperture 180 provided in a respective platelike member 150.

The method also includes the steps of forming a groove 140 in eachsubstantially flat surface of the compressible elastomeric pad 110 inabutting engagement with a peripheral side surface of the centralprojection 130, aligning the prongs 170 with the groove 140, piercingthe surface of the groove 140 and penetrating into the compressibleelastomeric pad 110. To enable prongs 170 to pierce both the centralprojection 130 and the groove 140, the diameter of the centralprojection 130 is sized based on the thickness of the prongs 170 so thatwhen each prong 170 pierces the exterior surface of the centralprojection 130, a portion of the prong 170 is exposed for piercing thesurface of the groove 140. The method additionally includes the step ofsizing the width of the groove 140 in a manner to align an exteriorperipheral edge of the groove 140 with an exterior surface of the prongs170.

The method also includes alternative steps of forming a plurality ofapertures 148 in abutting engagement with the peripheral side surface ofthe central projection 130, aligning the prongs 170 with the apertures148 and positioning each prong 170 within a respective aperture 148during application of the axial forming force.

The method includes the additional steps of positioning a predeterminedplurality of projections 160 a,b on the substantially flat surfaces ofeach of the pair of plate like members 150, forming an aperture 164through each of the predetermined plurality of projections 160 a,b andeach plate like member 150 and enabling the material of the compressibleelastomeric pad 110 to flow into each aperture 164 during cold formingprocess of the compressible elastomeric spring 100.

Although the above method has been described as caging the compressibleelastomeric pad 110 between the pair of plate like members 150, thepresent invention contemplates that at least one of such plate likemembers 150 may be replaced with a follower block 50, 60 or the centerplate 200, best shown and described in the co-pending U.S. Ser. No.12/150,777 entitled “Combination Yoke and Elastomeric Draft Gear” nowissued as U.S. Pat. No. 8,136,683 on Mar. 20, 2012.

In accordance with another embodiment, the invention provides a methodof making a multi-tiered compression spring assembly, generallydesignated as 102. Such multi-tiered compression spring assembly 102includes a predetermined plurality of axially disposed compressibleelastomeric pads 110, a first end plate 150 on one end of the assembly,a second end plate 150 on an opposed end of the assembly and a separatorplate 190 between each pair of adjacent compressible elastomeric pads110. The notable distinction in forming the multi-tiered compressionspring assembly 102 as compared to forming the compressible elastomericspring 100 is that the plurality of prongs 170 a, 170 b are formed onevery surface of the plates 190 which is in juxtaposition to one of thecompressible elastomeric pads 110.

It has been discovered that making the multi-tiered compression springassembly 102 in accordance with the above described method including thesteps of providing prongs 170, 170 a, 170 b formed on the plates 150,190 respectively, providing projection 130 and groove 140 formed on thecompressible elastomeric pad 110, as well as making the compressibleelastomeric pad 110 from a preselected copolyester polymer having amodified molecular structure and providing the compressible elastomericpad 110 with a predetermined shape factor provides for at least one ofaxial straightness and lateral stability enabling such multi-tieredcompression spring assembly 102 to repetitively cushion and absorb axialdynamic impact loads in excess of 7,500 pounds per square inch (PSI) andfurther within the range of between about 9,500 PSI and about 11,000 PSIin absence of a center rod or peripheral guidance.

The present invention further provides for a method of pre-shorteningthe multi-tiered compression spring assembly prior to its installationinto a conventional yoke, generally designated as 20. Now in referenceto FIG. 1, there is illustrated a multi-tiered compression springassembly, generally designated as 104, which includes a predeterminedplurality of compressible elastomeric pads 110 and plates 150, 190interlocked therebetween in accordance with the above describedembodiments. The method of pre-shortening the multi-tiered compressionspring assembly 104 also includes the step of adapting each of the rearfollower block 50 and the front coupler follower block 60 with means,generally designated as 450, for fixing the assembled multi-tieredcompression spring 104 at a predetermined pre-shortened height. In thepresently preferred embodiment of the invention, such means 450 includesa flange 452 rigidly secured to or integrally formed with each side edgeof each follower block 50, 60 and having an aperture 454 formedtherethrough. The flanges 452 are positioned on a respective followerblock 50, 60 in a manner aligning the opposed apertures 454 in the sameplane, which is shown as a vertical plane in FIGS. 1-2, when themulti-tiered compression spring assembly 104 is installed into the yoke20. Each follower block 50, 60 is operatively positioned at a respectiveend of the multi-tiered compression spring assembly 104 prior toapplication of the axial forming force. Thus, during forming, thecompressible elastomeric pads 110, plates 150, 190 and follower blocks50 and 60 are precompressed together. Then, the applied axial force ispartially removed enabling the multi-tiered compression spring assembly104 to return to a pre-shortened height which is smaller than the normalextended height of the multi-tiered compression spring assembly 104 andwhich enables installation of the multi-tiered compression springassembly 104 with the follower blocks 50, 60 into the yoke 20 in aconventional manner. Next, a pair of rods 456 having threaded ends 458are inserted through the aligned apertures 454. Fasteners, such asconventional threaded nuts 460 are operatively engaged at each threadedend 458 thus fixing the multi-tiered compression spring assembly 104 atthe predetermined pre-shortened height. When the predeterminedpre-shortened height of the multi-tiered compression spring 104 isfixed, the applied axial forming force is removed completely. After themulti-tiered compression spring assembly 104 is installed into the yoke20, as best shown in FIG. 2, the nuts 460 are disengaged, preferablygradually and equally at each side of the multi-tiered compressionspring assembly 104, from each threaded end 458, the rods 456 areremoved and the multi-tiered compression spring assembly 104 is allowedto extend to its normal operating height and being maintained in aconventional preload condition, generally being defined by a preloadforce of between about 20,000 pounds and about 50,000 pounds. It wouldbe appreciated that the preload condition will apply to variousembodiments of the compressible elastomeric springs 100, 102 describedin the co-pending applications.

Thus, the present invention has been described in such full, clear,concise and exact terms as to enable any person skilled in the art towhich it pertains to make and use the same. It will be understood thatvariations, modifications, equivalents and substitutions for componentsof the specifically described embodiments of the invention may be madeby those skilled in the art without departing from the spirit and scopeof the invention as set forth in the appended claims.

We claim:
 1. (canceled)
 2. (canceled)
 3. (canceled)
 4. (canceled) 5.(canceled)
 6. (canceled)
 7. A method of making a multi-tieredcompression spring assembly including a plurality of axially disposedcompressible elastomeric pads and a plurality of separator plates, saidmethod comprising the steps of: (a) forming an axial aperture though athickness of each of said plurality of separator plates; (b) positioninga plurality of prongs on or in close proximity to a peripheral edge ofsaid axial aperture; (c) extending said plurality of prongs at an anglerelative to a surface of said plates which is in juxtaposition to one ofsaid plurality of compressible elastomeric pads; (d) positioning saidseparator plates and said plurality of compressible elastomeric pads inseries with each other to form said multi-tiered compression springassembly, wherein each separator plate is disposed between a pair ofcompressible elastomeric pads; (e) applying an axial force to one end ofsaid multi-tiered compression spring assembly; (f) piercing, with saidplurality of prongs and said applied force, an axial end of arespectively juxtaposed compressible elastomeric pad; (g) penetrating,with said plurality of prongs and said applied force, a predetermineddistance into said respectively juxtaposed compressible elastomeric pad;and (h) mechanically interlocking, by way of said prong penetration,said plurality of compressible elastomeric pads with said plates
 8. Themethod, according to claim 7, wherein said method includes theadditional step of removing said axial force from said multi-tieredcompression spring assembly and the step of pre-shortening saidmulti-tiered compression spring assembly prior to removing said axialforce.
 9. A method of providing at least one of axial straightness andlateral stability in a multi-tiered compression spring assembly duringrepetitive cushioning of repetitive axial dynamic impact loads in excessof 7,500 pounds per square inch (PSI) and in absence of a center rod orperipheral guidance, said spring assembly including a plurality ofaxially disposed compressible elastomeric pads formed from a preselectedcopolyester polymer having a modified molecular structure, saidplurality of axially disposed compressible elastomeric pads having apredetermined shape factor and a separator plate between each pair ofadjacent compressible elastomeric pads, said method comprising the stepsof: (a) forming each axial end of each of said plurality of pads with anaxial projection; (b) forming said each axial end with a groove inabutting relationship with a peripheral side surface of said axialprojection; (c) forming an axial aperture though a thickness of eachseparator plate; (d) providing a plurality of prongs positioned on or inclose proximity to a peripheral edge of said axial aperture andextending at an angle relative to a surface of said each separator platewhich is in juxtaposition to one of said plurality of compressibleelastomeric pads; (e) positioning said separator plates and saidplurality of compressible elastomeric pads to form said multi-tieredcompression spring assembly; (f) aligning said plurality of prongs witheach of a respective axial projection and groove; (g) applying an axialforce to one end of said multi-tiered compression spring assembly; (h)piercing, with said plurality of prongs and said applied force, each ofan exterior surface of said axial projection and a surface of saidgroove of a respectively juxtaposed compressible elastomeric pad; (i)penetrating, with said plurality of prongs and said applied force, apredetermined distance into a thickness of said respectively juxtaposedcompressible elastomeric pad; and (j) mechanically interlocking, by wayof said prong penetration, said plurality of compressible elastomericpads with said separator plates
 10. (canceled)
 11. (canceled)
 12. Themethod of claim 7, further including the additional steps of providingat least one additional plate and positioning said at least oneadditional plate at at least one end of said multi-tiered compressionspring assembly prior to applying said predetermined axial force in step(e).
 13. The method of claim 7, further including the additional stepsof providing an axial projection on at least one end surface of eachcompressible elastomeric pad and the step of piercing an exteriorsurface of said axial projection.
 14. The method of claim 13, furtherincluding the additional step of exposing a portion of each of saidplurality of prongs.
 15. The method of claim 7, further including theadditional steps of providing an axial groove on at least one endsurface of each compressible elastomeric pad and the step of aligning anexterior peripheral edge of said groove with exterior surfaces of saidplurality of prongs.
 16. The method of claim 7, further including theadditional steps of positioning a plurality of projections on eachsurface of said each separator plate and forming an aperture throughthicknesses of each of said plurality of projections and said eachseparator plate.
 17. The method of claim 7, further including the stepof providing an axial projection on each end of each of said pluralityof compressible elastomeric pads and the step of forming a groove ineach end surface of said each of said plurality of compressibleelastomeric pads in abutting engagement with a peripheral side surfaceof said axial projection prior to applying said axial force in step (e).18. The method, according to claim 7, further comprising the additionalstep of axially precompressing each of said plurality of compressibleelastomeric pads to a predetermined height.
 19. The method, according toclaim 13, wherein said method further includes the step of axiallyextending said axial projection into said axial aperture.
 20. The methodof claim 9, further including the step of mounting an additional plateat each end of said multi-tiered compression spring assembly prior toapplying said axial force in step (g).
 21. The method, according toclaim 9, further comprising the additional step of axiallyprecompressing each of said plurality of compressible elastomeric padsto a predetermined height.